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El Caño Archaeological Park:
Biodiversity Past and Present
Interactive Qualifying Project Completed in Partial Fulfillment of the
Bachelor of Science Degree at
Worcester Polytechnic Institute
Submitted:
October 10th, 2019.
By:
Connor Bourgeois, Mechanical Engineering
Lokesh Gangaramaney, Mechanical & Robotics Engineering
Jax Sprague, Mechanical Engineering
Luke Trujillo, Computer Science & Robotics Engineering
Submitted to:
IQP Advisor: James A. Chiarelli, Interdisciplinary and Global Studies Division.
Prof. Aaron R. Sakulich, Panama Project Center Director.
Sponsors: Rick Montanari, Footprint Possibilities Inc.
Alexa Hancock, Fundación El Caño.
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TABLE OF CONTENTS
TABLE OF CONTENTS ii
LIST OF FIGURES iii
ABSTRACT iv
ACKNOWLEDGEMENTS v
AUTHORSHIP vii
EXECUTIVE SUMMARY viii
CHAPTER 1: INTRODUCTION 1
CHAPTER 2: BACKGROUND 4
2.1 Classification of Flora 4
2.2 Panamanian Flora and Climate 4
2.3 Archaeological Sites in Central America 6
2.4 El Caño Archaeological Park 7
2.5 Pre-Columbian Civilizations 9
2.6 Maya Subsistence 10
2.7 Modern Farming Practices in Panama 12
CHAPTER 3: METHODOLOGY 14
3.1 Sample Collection 14
3.2 Plant Identification 17
3.3 Data Synthesis 19
3.4 Limitations 20
CHAPTER 4: RESULTS 22
4.1 Findings 22
4.2 Native, Non-Native, and Invasive Species 23
4.3 Significance of Identified Species 27
CHAPTER 5: CONCLUSIONS 29
5.1 Analysis 29
5.2 Moving Forward 30
REFERENCES 31
IMAGE REFERENCES 34
APPENDIX A: LIST OF PLANTS IDENTIFIED 35
APPENDIX B: SAMPLES OF THE PLANTS IDENTIFIED WITH LABELS 41
APPENDIX C: XILOTECA AND VACUUM-SEALED FRUITS 63
APPENDIX D: SATELLITE IMAGERY OF EL CAÑO 65
APPENDIX E: PHOTOS OF THE HERBARIUM PRESS 69
APPENDIX F: FOLDER FILING SYSTEM EXAMPLE 71
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List of Figures
Figure 1: Visiting El Caño Archaeological Park 7
Figure 2: Gold artifacts found during excavations of Pre-Columbian tombs 8
Figure 3: Sample collection 14
Figure 4: Clamping the plant press 15
Figure 5: Collecting data in the field 16
Figure 6: Determining the location with GPS 16
Figure 7: Identifying the plants using apps 17
Figure 8: Invasive vs. non-invasive species in the park 24
Figure 9: Native vs. non-native species in the park 25
Figure 10: Map of GPS coordinates of plant species 26
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ABSTRACT
Panama's El Caño Archaeological Park documents a process of cultural evolution resulting
in stratified social structures in Pre-Columbian societies. To better understand the specific culture
of this region, Fundación El Caño, the foundation conducting research at the archaeological site,
has undertaken a comparative study of flora specimens found in archaeological contexts and flora
currently present in the park. To aid with their study, over 40 unique species were identified in the
park and many of them were preserved as herbarium specimens through approved botanical and
archival techniques. Flora specimens were collected, pressed and dried, mounted, identified,
labeled, and prepared for curation at Museo El Caño as a comparative collection for future
reference and continued study.
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ACKNOWLEDGEMENTS
Our team would like to acknowledge the help and consideration of those who advised and
contributed to the success of the project. We extend our warmest gratitude and thank those who
guided the project to fruition.
We would first like to extend our thanks to Alexa Hancock and all the employees who
provided an opportunity to work at El Caño Archaeological Park. With Alexa’s help and guidance,
we were able to gain an understanding of our deliverables to the foundation and the scope of our
work. Moreover, she directed us with a tour of the park, pointing out where we could find the most
biodiverse regions.
We would also like to thank Rick Montanari and the rest of Footprint Possibilities for
supplying hardware necessary for our project that would have been difficult to source within
Panama. The pieces of hardware given to us, such as heavy-duty clamps, a vacuum sealer, and a
Garmin GPS, were all pivotal in allowing us to successfully document and preserve our procured
samples. Weekly meetings with Rick have also helped us stay on a tight schedule and pushed us
to attempt different preservation methods, which ultimately inspired us to create large-scale plant
presses inducing more force, halving the projected drying time for plant specimens.
The project would not have been possible without the help of our advisors Prof. James A.
Chiarelli and Prof. Aaron R. Sakulich. Our advisors provided us guidance, assistance, and general
help whenever needed for the completion of our project. Prof. Chiarelli, in addition to directing
our D-Term ID 2050 seminar, provided us with his valuable time and guidance in helping our
project develop from a prompt to a complete deliverable for our sponsors. Prof. Sakulich provided
us with constructive criticism on our project and guidance in helping our project meet all the
requirements of an IQP. Moreover, Prof. Sakulich and the WPI Civil Engineering department also
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provided generous financial support for the supplies and equipment necessary for carrying out our
fieldwork.
Our team would like to extend our gratitude to the WPI Global Projects Program for
affording us this opportunity to go abroad for the completion of our IQP. Our team is grateful for
the comfortable stay in Panama and the assistance provided by the program for the successful
completion of the project.
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AUTHORSHIP
Connor Bourgeois:
Connor created the folder filing system to organize the images of the plants in a clear manner,
adding ID numbers to group each plant and facilitate species identification. He also helped in the
field with collecting samples, taking photos of the team working, and tracking the GPS location.
Connor identified a few plants. He assisted in the construction of the plant press.
Lokesh Gangaramaney:
Lokesh collected most of the samples in the field. He identified several plant species. Lokesh
created labels for the herbarium specimens, printed them out, and helped Jax attach them to the
specimens. He also wrote several sections of the paper, including the Abstract,
Acknowledgements, Executive Summary, parts of the Background, and the Appendices. Lokesh
contributed largely to the poster, particularly the format. He researched materials for the herbarium
collection and sourced the scrapbook and page protectors.
Jax Sprague:
Jax served as the primary author of the paper, having contributed to the Abstract, Executive
Summary, Introduction, Background, Methodology, Results, and Conclusions. She also proofread
the paper and poster. In the field, Jax recorded data in a notebook about each plant and took pictures
of the team working. She identified the majority of the plant species. She researched materials for
the project and helped source them. Jax pieced together the herbarium collection, mounting them
and placing them in the scrapbook with Luke and attaching labels with Lokesh. Jax and Luke
created the final presentation for the project. She researched most of the plant species’ cultural
significances.
Luke Trujillo:
In the field, Luke collected GPS data, measured the height, and took photos of each plant. He
discovered alternate methods to construct the plant press. Luke aided in mounting the specimens
to herbarium paper and placing them in the scrapbook. He created the spreadsheet containing all
the information about the plants and transcribed the information from the notebook to the sheet,
which was formatted into the labels. Additionally, he created a map of the GPS location of each
plant species and figures detailing the native, non-native, and invasive species. For the paper, Luke
contributed to the Executive Summary, Results, and Conclusion. He researched some of the plant
species’ cultural significances.
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EXECUTIVE SUMMARY
Background
El Caño Archaeological Park in Panama documents a long history of socio-cultural
evolution during the Pre-Columbian era. Our sponsor, Fundación El Caño, has undertaken a
comparative study of the flora found in El Caño Archaeological Park today and the flora found in
archaeological contexts during the excavation of Pre-Columbian tombs. By analyzing and
comparing contemporary and ancient flora, archaeologists can observe how the environment of El
Caño has changed over time in response to human activities and natural processes that have altered
the landscape and, possibly, climate change. This will also provide insight as to how this
civilization lived, discovering the crops they used for tools, food, shelter, and clothes.
To classify the species within the park, the team learned the basic concepts of plant
taxonomy - the science of finding, identifying, describing, classifying, and naming plants. The
hierarchy of classification is kingdom, phylum, class, order, family, genus, and species. Genus and
species are used for the species name of each plant. Panama contains approximately 10,000 unique
plant species. It has a tropical climate with a wet and dry season, both spawning very different
environments. Some common plants in Panama are heliconia, hibiscus, ginger, and bougainvillea.
Pre-Columbian cultures in Central America are known for their complex societal structures
and advanced technologies that much of the world had yet to discover. Some Pre-Columbian
cultures produced complex writing systems and developed their own literature. Their cities are
recognized for their pyramids, plazas, and palaces, as well as ball courts and stone monuments.
Lower status families lived in adobe homes. Homes had amenities for sleeping, cooking, eating,
worship, and steam bathrooms. The nobility had similar room dedications but on a much larger
and grander scale.
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Methodology
To accomplish this goal, we created three main objectives guiding the project:
1. Collect information on each unique plant in El Caño Archaeological Park.
2. Use Pl@net, iNaturalist, and PictureThis applications to identify the plants.
3. Create a spreadsheet to synthesize the data.
For collecting smaller plants, specimens that possessed many of the plant’s organs were
chosen: stems, flowers, fruits, and leaves. The team made plant presses from two sheets of plywood
layered with several additional sheets of cardboard. Newspaper lined the cardboard and the plants
were situated so as to not overlap when pressed. Heavy-duty mechanical clamps secured the press,
increasing pressure and reducing drying time to two weeks. From there they were glued onto
moisture-absorbing, acid-free watercolor paper and placed in a page-protected scrapbook.
In order to keep the herbarium specimens scientifically significant, we recorded their
scientific name, family, location, habitat, growth habit, frequency, height, color, collector’s name,
species determiner’s name and collection date on the sheet, numbering them as they were collected.
This information was recorded in a spreadsheet before transferring them onto labels. These labels
were printed and taped on the page protectors of their corresponding plants.
For the trees of the park, we constructed a xiloteca. Specimens were collected by sawing
off a portion of the trunk revealing the outer bark pattern. These samples were placed inside a clear
briefcase and labeled with the number that corresponded to their identity in the spreadsheet. Fruits
were vacuum sealed and labeled with their species name and identity number.
The team utilized the apps Pl@ntNet, iNaturalist, and PictureThis to identify flora in El
Caño Archaeological Park. These apps allow the user to select an image of an organ of the plant
and compare it to visually-similar plants in order to determine the species.
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For data organization, we created a filing system with folders for the various family names
of the identified specimens. From there, subfolders were made with the genus names. Inside the
genus, folders are subfolders for the different species identified. Photos of each plant were placed
in their respective species folders as they were identified.
Results and Conclusions
Initially the team set out to preserve 25 specimens and identify a total of 50 at El Caño.
Upon further investigation of the biodiversity, the team preserved 32 unique specimens and
identified 44 total species. From there, the specimens collected were classified into a large variety
of habits. After all specimens were identified, the team investigated the origin and invasiveness of
each species. Of all the specimens, 8 were found to be invasive, 23 were found to be native, and
21 were found to be non-native. Most of the specimens that the team identified were found to have
a wide variety of historical and medicinal uses.
The team concluded that the environment of the park has largely changed since Pre-
Columbian times due to bird droppings, landscaping, flooding, and agriculture. In addition, the
biodiversity is quite different during wet and dry seasons, so the team recommends that Fundación
El Caño repeat this study during the dry season to ensure all species were found.
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CHAPTER 1: INTRODUCTION
El Caño Archaeological Park is one of the most important Pre-Columbian sites in Panama.
Since the discovery of El Caño, excavations of the site have given historians a better understanding
of the cultural evolution and social structure of ancient Panama and surrounding Central American
nations in the Pre-Columbian era. Fundación El Caño, the foundation that conducts research and
maintains the site, has undertaken a comparative study of the contemporary flora in the park and
the ancient flora discovered during excavations of Pre-Columbian tombs. Our team identified all
the park’s flora and reported our findings in this document.
The identification of flora is necessary as it allows researchers to assess important
rangeland and inland pasture variables that are critical to the proper management of any area or
national park. With proper knowledge of a national park, management can assess range conditions,
proper stocking rates, forage production, wildlife habitat quality, and rangeland trends (“Plant
Identification: Is It Worth the Effort?” n.d.). Moreover, with the proper identification of flora, the
management can keep track of the ecological and environmental changes within the park over
time. Therefore, with the completion of the project, our sponsor would be able to conduct a study
of how the park's ecology and environment have changed since Pre-Columbian times.
The team cataloged the flora of El Caño by first collecting specimens according to proper
conservation guidelines. We placed the flowering plants in herbariums and woods in a xiloteca. A
xiloteca is a special form of herbarium for the collection of authenticated wood specimens
(“Xylarium,” n.d.). Afterward, we identified the most prominent flora of the region through
quantification and used plant identification software to identify individual plants. We took note of
every plant’s prominence and location at El Caño Archaeological Park. After thoroughly
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identifying and quantifying the parks flora, we compiled a spreadsheet detailing our findings and
provided this to our sponsor.
The organization hosting the biodiversity project in Panama City is Footprint Possibilities,
a non-governmental organization based in Panama. Footprint Possibilities’ mission includes
“organizing and seeking funding for local community efforts (“About Us,” n.d.).” Past projects
include supplying impoverished people with healthy foods and vitamins, disposing of wastewater,
providing access to clean water, improving the infrastructure of local community centers, and
increasing educational and cultural opportunities all with the goal of improving basic health
conditions (“Welcome to Footprint,” n.d.). Footprint Possibilities expanded to help those in need
in other countries, such as Ghana, although most of the projects occur in Panama (“Projects,” n.d.).
By working with Engineers Without Borders and other collaborating organizations and institutions
like Worcester Polytechnic Institute, more people may join the effort to assist those in need.
Engineers Without Borders is an organization that “[partners] with communities to meet
their basic human needs (“Mission & History,” n.d.).” By building sustainable structures,
providing renewable energy, and digging for water, Engineers Without Borders provides
opportunities for communities to thrive. Engineers Without Borders chapters from around the
world engage in projects in Panama, like cleaning the Panama water supply in remote regions
(Brymer, 2019). Worcester Polytechnic Institute has worked with Footprint Possibilities in the
past. In 2019, they are collaborating with them on two projects: accessibility and biodiversity in
El Caño Archaeological Park.
Fundación El Caño is a Panamanian foundation that works with El Caño Archaeological
Park in order to preserve and study ancient heritage. Footprint Possibilities is teaming up with
Fundación El Caño to make the El Caño Archaeological Park a better place for tourists to
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understand and appreciate Panamanian history. This is done by making the park accessible to
tourists and discovering the various flora that exists around the Pre-Columbian ruins. The end goal
is to make El Caño a valuable place maintained for the community’s economic and cultural benefit
(“Parque Arqueológico El Caño,” n.d.).
The importance of this project stems from the need to compare ancient societies to those
of today. By analyzing the flora today and the flora from other Pre-Columbian sites and tombs, we
can see how the ecology and environment have changed over time. Based on the flora in El Caño,
we can determine how the Pre-Columbian civilization lived, as we will see the types of plants they
could use for tools, food, shelter, clothes, and anything else they may have used in their daily lives.
Observing the El Caño plant life will increase the historical importance of the park and allow
visitors to peek into the lives of ancient societies (Barlow, 2012).
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CHAPTER 2: BACKGROUND
2.1 Classification of Flora
The classification of flora can be a tedious process. The science of classifying living
organisms is called taxonomy by which each organism is classified into its appropriate kingdom,
phylum, class, order, family, genus, and species. Using this multi-tiered classification system
allows scientists and researchers to easily identify the relationship between different organisms.
Organisms are given a binomial name, which is the scientific name starting with the name of the
organism's genus, and the common name, which is what the organism is commonly called
(Takhtadzhian, 1997).
2.2 Panamanian Flora and Climate
Panama and Central America in general form a land bridge between North and South
America, creating great biodiversity. Experts estimate there to be over 10,000 species of plants in
the rainforests, coastlines, and highlands of Panama. Some common flowers are the heliconia,
hibiscus, ginger, and bougainvillea (“Flora and Fauna of Panama,” n.d.). There are about 675
species of orchids in Panama as well (“Plants, n.d.). Other plants include cocoa pods, Arabica, and
Geisha coffee cherries (Fallon, 2016). Of the 1,500 species of tropical trees, common trees include
the Ceiba, Guanacaste, Strangler Fig, Cecropia, and Gumbo Limbo (“Flora in Panama,” n.d.).
The vegetation near the canal mostly resides in the humid, tropical rainforest (“Plants,”
n.d.). A rainforest is a tall, dense jungle that receives a high amount of rainfall each year. The
climate of a rainforest is very hot and humid. Rainforests contain four different layers: the
emergent layer, canopy layer, understory layer, and forest floor. The emergent layer contains the
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tallest trees, often broad-leaved, hardwood evergreens requiring plenty of sunlight. The canopy
layer forms a roof over the rest of the rainforest. Trees in this layer have smooth, pointed, ovular
leaves. The understory layer does not receive much sunlight, so the leaves grow to be much larger.
On the forest floor, there is almost no sunlight and as a result, very few plants. Plant matter decays
quickly in this region as well (“What is a Rainforest?” n.d.)
The Pacific Coast has tropical dry forests and grasslands (“Plants,” n.d.). A tropical dry
forest contains a pronounced dry season during the year, provoking adaptations in plant and animal
life. Many tree species are deciduous, shedding their leaves at the start of the dry season, and many
plant species evolved for water retention (“Tropical Dry Forests,” n.d.). Grasses dominate
grasslands, which have little to no tree cover. Grasslands possess diversity in herb and grass
species, despite not having trees or shrubs (“Grasslands,” n.d.).
Highlands have cloud forests, the highest peaks have alpine vegetation, and the coasts have
mangrove forests (“Plants,” n.d.). A cloud forest is a tropical evergreen montane forest with high
levels of condensation appearing as mist or cloud coverage at the canopy level. Cloud forests have
100% humidity at all times of year. In eastern Panama, cloud forests exist at an altitude of 750
meters and in western Panama, they are at 2,200 meters. Cloud forests have high levels of rainfall
(Karuga, 2017). Alpine vegetation consists of plants that grow above the tree line in an alpine
climate. These plants include graminoids, forbs, and mosses (“Alpine Vegetation,” 2014). A
mangrove forest is a group of trees and shrubs on the coastal intertidal zone (NOAA, 2018). Over
29 percent of Panama's land is protected in the form of national parks and wildlife reservations,
allowing for biodiversity to prosper in these regions (“Plants,” n.d.).
2.3 Archaeological Sites in Central America
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In order to further understand our goals for El Caño, it is paramount to learn about other
major archaeological parks in Central America - namely their history, culture, and the type of flora
they host. One site that holds its rank among the wonders of the ancient world is Chichen Itza, on
Mexico’s Yucatan Peninsula. It was founded in the 6th century CE by the Maya, who are presumed
to have occupied the region since the Pre-Classic period. Evidence shows that after the collapse of
Classic Maya civilization around 900 CE, the site was invaded by foreigners, probably other
Mayan speakers who had been strongly influenced by the Toltec of central Mexico. One of the
significant cultural practices was the tradition of the Cult of Cenote, which involved human
sacrifice to the rain god. The sacrificial victims were thrown into the city’s major cenote (a body
of water exposed in a sinkhole by collapsed limestone surface crust) along with their gold and jade
ornaments (Britannica, 2018). The site hosts a variety of flora, mainly Yucatan Flora. It consists
of Passion Fruit, Pitaya, Shaving Brush Trees, Plumeria – Frangipani Trees, African Tulip, Golden
Shower Trees, and many more (“Yucatan Adventure Geo-Travel Guide,” n.d.).
The second site with Maya is Copan, Honduras. Evidence of people in the Copan Valley
dates to 1500 B.C. The Maya leader Yax Kuk Mo, who came from the area of Tikal, arrived in the
Copan Valley in 427 CE and started a dynasty of 16 rulers that transformed Copan into one of the
greatest Maya cities during the Classic Maya Period (Centre, U.W.). The site has an abundance of
tall, slender trees festooned with long moss with a dense undergrowth of shrubs.
Belize is home to Caracol, the country’s largest known Maya archaeological site. Caracol
is not as well-excavated as many other Maya sites but has Caana – the largest Maya pyramid in
the country, as well as the tallest man-made structure in Belize to this day. Guatemala’s Tikal is
well-excavated and restored in a tropical jungle, filled with temples, parrots, and howler monkeys.
Tikal could once support approximately 100,000 people as it covered 65 square kilometers in its
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prime. Joya de Cerén in El Salvador provides the most accurate glimpse into ancient Maya life as
the remains of the Maya village were buried under volcanic ash 1,400 years ago. Nicaragua has
Huellas de Acahualinca and León, and Panama has Casco Viejo, all ruins that display the
architecture and lifestyles of ancient civilizations charred by volcanoes (“The Most Intriguing
Historic Sites in Central America,” n.d.). In addition to Tikal, Guatemala has Yaxhá, an ancient
Maya city in the jungle with many temples, and Aguateca, a city on top of a 90-meter-tall limestone
bluff (“10 Top Archaeological Sites from Mexico to Peru,” 2012). Although the people of El Caño
were at best only distantly related to the Maya and other major Pre-Columbian peoples, ancient
Mesoamerican and Central American societies shared many of the same cultural traits and
traditions.
2.4 El Caño Archaeological Park
Figure 1: Worcester Polytechnic Institute students visiting El Caño Archaeological Park for the
first time. Photo taken by Alexa Hancock.
El Caño Archeological Park is located on the Pacific side of Panama, west of Panama City,
and near Rio Grande. The village of El Caño is in the city of Penonomé in the province of Coclé.
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Comprising of different structures, the sites' excavations between 2008 and 2011 allowed the
discovery of several lavish burials estimated dated between 700 and 1000 CE. The excavation also
revealed data that served as a source of information on the Pre-Columbian chiefdoms and their
mortuary practices. The tombs were found in multiple levels and the warriors were bathed in gold,
which made the discovery one of the most significant discoveries in Central America. The analysis
of the tombs reveals their society followed a form of hierarchical organization. However, the more
unusual finding was the bones of very poisonous blowfish, which could have been used to kill all
the people that were presumed to have been sacrificed for the chief (Johnblack, 2014). Currently,
there is little to no information about the flora in the park available online; however, with this
project, our team sought to change that.
Figure 2: Gold artifacts found during excavations of the tombs in El Caño Archaeological Park.
Photo taken by Dra. Julia Mayo, Director of Fundación El Caño.
The village of El Caño is home to a water irrigation system used to grow staple grains like
rice, maize, beans, sorghum, and soy; fruits and vegetables like mango, papaya, cashews, melons,
tomatoes, red peppers, onions, squashes, and citrus; and other crops like sugarcane and forages.
Rice is the predominant crop of the region. Because this land has been used for farming, soil quality
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has likely altered due to the use of the land for cultivating specific crops rather than what has
grown natively in the region (Peccei, 1991). The archaeological site was once part of a sugarcane
plantation. Fundación El Caño has stated that in 1973, the company that owned the archaeological
site destroyed several mounds while working for the plantation, leading to the creation of the park
to preserve the remains (“Cultural Gold Artifacts Now on Display to Public,” 2019).
2.5 Pre-Columbian Civilizations
Pre-Columbian cultures in Central America are known to be surprisingly innovative and
advanced, inventing many technologies that the rest of the world had yet to discover. Many Pre-
Columbian cultures produced complex writing and calendrical systems and developed their own
literature concerning religion, time, astronomy, history, power, legacy, mythology, and fiction.
These writings say much about the interests, rituals, and focuses of the cultures (“Pre-Columbian
Literature: The 8 Most Important Features,” n.d.). Maya is known to have the only writing system
that represented the spoken language, whereas other cultures had more pictographic written
languages. Due to the trading networks, each Pre-Columbian culture influenced the others, which
explains the shared characteristics of the cultures (“Distinctive Features of the Maya Culture,”
n.d.).
Geographically speaking, Pre-Columbian cultures occupied rainforests, savannas, arid
plateaus, mountains, and swamps. This collection of landscapes gave to rich biodiversity in flora
and fauna, so each civilization would have had different environments in which they built their
civilizations. This creates diversity in diets, clothing, shelter, and tools (“Distinctive Features of
the Maya Culture,” n.d.).
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From a religious standpoint, many civilizations had temples and believed in a cyclical
timeline. Aztecs and Maya practiced human sacrifice to the gods to improve and ensue longevity
of their society. Religion was central to their lifestyles. Religious rituals revolved around the
terrestrial and celestial cycles, as well as the natural world. They believed in birth, death, and
rebirth (“Distinctive Features of the Maya Culture,” n.d.).
Cities are recognized for their pyramids, plazas, and palaces, as well as ball courts and
stone monuments (“Distinctive Features of the Maya Culture,” n.d.). Many poor families lived in
adobe homes. Homes had sleeping, cooking, eating, worship, and steam bathrooms. The nobility
had similar room dedications but on a much larger scale. While in an adobe home, sleeping,
cooking, eating, and worship would occur in one building with a separate building for saunas, the
nobility would have large rooms dedicated to each (“Aztec Culture,” n.d.).
Although the people of El Caño were not Maya or Aztec, their culture was probably very
similar. We know that El Caño had complex nobility structures, as did the other Pre-Columbian
societies. Panama lies outside of the Mesoamerican border, but with the vast trading systems of
each culture, they likely led similar lifestyles. By researching more understood Pre-Columbian
societies, we can better understand what is found in the tombs and how they lived.
2.6 Maya Subsistence
The Maya were an agricultural society, and approximately 90% of their population was
involved in farming in some way. Since they inhabited many locations with varying soil quality,
different branches of Maya farmed in different ways. To increase soil fertility, the Maya would
raise fields and create stone-wall terraces to collect fertile silt deposits. They used slash-and-burn
techniques to rejuvenate land after two years of planting since deforestation would create infertile
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soil if nutrients were not periodically replenished. Slash-and-burn agriculture is the process of
cutting down crops and burning the field (“Slash and Burn Agriculture,” n.d.). The slash-and-burn
technique would take about 5-7 years for soil to be ready for planting again. In highland regions,
plots had to be left empty for up to 15 years. Due to the short planting period, productivity was
maximized by planting squash and beans in fields of maize so the beans could climb the maize
stocks and the squash would hinder soil erosion. Cities without access to large plots would trade
slaves, salt, honey, metals, feathers, and shells for food. Private homes had small gardens that
cultivated fruits and vegetables. After harvesting, foods were stored in above-ground wooden
cradles. Water was collected in collapsed caves and cisterns and brought to fields through canals
(Cartwright, 2015).
Important crops were maize, sweet manioc, beans, squash, amaranth, and chili peppers.
Fruits grown were guava, papaya, avocado, custard apple, and sweetsop. They also used chocolate,
honey, agave, sapodilla, breadnut, bottle gourd, copal, and cotton (Cartwright, 2015).
Domesticated animals that were raised for food included dogs, doves, turkeys, Muscovy ducks,
coatimundi, and deer. Over time, certain dogs became hunting companions. Since not many
animals could be domesticated, wild animals were the primary source of protein. Peccary, deer,
tapir, agouti, paca, squirrel, rabbit, manatee, chachalaca, crested guan, turkey, and curassow were
some wild animals and birds taken for meat. Some birds were taken for their plumage as feathers
were important trade items: Scarlet Macaw, quetzal, and other parrots were not eaten but still
captured and killed. Fish were likely captured with cotton nets, although the remains were mostly
deteriorated due to their acidity (Smith, n.d.).
Gaining an understanding of the subsistence of other Pre-Columbian societies, particularly
the crops they grew, creates an idea of what may be found within the park. The flora currently in
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the park may be descendants of what Pre-Columbian societies grew, but more likely the flora found
in the tombs will match the subsistence of that era.
2.7 Modern Farming Practices in Panama
Agriculture in Panama today is faced with multiple issues. Panamanian farmers are plagued
with water pollution and poor farming practices that threaten soil siltation and degrade the land.
Several organizations are promoting sustainable agricultural practices in Panama to improve the
land. ECOFARMS is looking to protect and restore the rainforest around Mamoni River Valley by
working with local communities to reduce chemical additives and instead work with organic
materials in farming processes. Planting Empowerment is rebuilding tropical forests from
deforested land to maintain sustainable agriculture and improve the health of the region and make
the local communities more economically independent. Women Farmers Alliance teaches farmers
crop rotation, organic fertilizer, and organic pest control while training women so farming becomes
gender-equal, an equal opportunity career option. Sustainable Harvest International partnered with
local farmers to increase access to clean water during the dry season by developing a protected
watershed preserve (DeRoche, 2018).
Crops that are commonly cultivated and exported in Panama today are avocados, mangoes,
and teak wood. These crops are perfectly suited for the Panamanian climate and soil quality and
have high demand globally. Harvesting them improves the Panamanian economy as they are a
solid investment opportunity for foreigners. Panama is the second largest Free Trade Zone in the
world, their currency is in USD, there are no restrictions on foreign ownership, and there aren’t
any exchange controls. With proper farming techniques, there can be up to two farming cycles per
year. Overall, agriculture is a high-demand industry in Panama (DeSa, 2017).
13
Learning about modern farming practices in Panama shines light on how the environment
of El Caño may have changed from human interference. Seeing as it was once part of a sugarcane
foundation and the region has farmland, the agricultural practices currently in place will have an
effect on the land today. If altered enough, the original plant life in El Caño would not be able to
grow today. It is imperative to know how the land is changing to complete this comparative study.
14
CHAPTER 3: METHODOLOGY
The goal of this project was to identify all the flora present in the El Caño Archaeological
Park in order to give our sponsors Footprint Possibilities and Fundación El Caño all the necessary
information needed to conduct a study of how the area’s ecology has changed over time. This
study would give the sponsor a better understanding of how the Pre-Columbian civilizations lived
in their era. Initially, there was little understanding of what kind of flora was present in the park,
and our project addressed this. We found the following methods would be the best way to identify
the flora present in El Caño archaeological park.
1. Collect data of each unique plant
2. Use Pl@ntNet, iNaturalist, and PictureThis Applications for identifying the plants
3. Create a spreadsheet for synthesizing our data
3.1 Sample Collection
Figure 3: Lokesh Gangaramaney snipping a sample of a vine to be pressed, identified, and
mounted. Photo taken by Jax Sprague.
For the smaller plants, grasses, and flowers, we built an herbarium to properly analyze the
data. Before collecting each species, we made sure we had the permissions to do so. This was to
follow proper conservation efforts in place in Panama. Specimens that possessed many of the
plants’ organs - primarily stems, flowers, fruits, and leaves - were chosen. We detailed the height
of the plant so the entire length of the stem would not have to be dried, but made sure to include
15
basal, lower, and middle leaves. Fruits were vacuum-sealed, labeled, and attached to the sheet with
the rest of the plant. Thick flowers were cut in half before continuing with the preservation process
so they could be properly pressed, dehydrated, and mounted. In order to prevent wilting in the
plants, they were immediately pressed after collection in a handmade plant press. We made the
plant presses with two pieces of thick plywood layered with several sheets of cardboard.
Newspaper lined the cardboard and the plants were situated so as to not overlap when pressed. To
secure the press, we applied heavy-duty clamps, increasing the pressure and reducing drying time
(“How to Make a Herbarium Specimen,” n.d.). In order to maintain uniform pressure inside the
press, the clamps were applied at the center of each edge as well as every corner. To speed up the
drying process, newspaper sheets were changed every few days as they absorbed moisture from
the plants (Appendix E).
Figure 4: Jax Sprague securing the clamps on the plant press to accelerate the drying process.
Photo taken by Luke Trujillo.
In order to keep the herbarium specimens scientifically significant, we marked their
scientific name, family, location, habitat, growth habit, frequency, height, color, and date on the
sheet and numbered them as they were collected. The collector and species determiner’s names
were also recorded. We recorded this information in a spreadsheet (Appendix A) before
transferring them onto labels. These labels were printed and glued onto watercolor paper, which
we used as mounting paper. Plants were arranged on the sheets in a lifelike manner before
attaching. We glued the plants to the sheets with epoxy and pressed the sheets for two hours to
16
ensure they would not detach from the paper (Frank & Perkins, 2017). To store the individual
sheets, we placed them in plastic protectors and then in a binder containing each of the herbarium
specimens (Appendix B).
Figure 5: Luke Trujillo taking photos of the plant to run through the identification software and
Jax Sprague recording data about the plant’s location and visual description. Photo taken by
Connor Bourgeois.
Figure 6: Connor Bourgeois using the GPS to determine the precise location of the plant
specimen in the park. Photo taken by Jax Sprague.
17
For the trees of the park, a xiloteca was constructed (Appendix C). Specimens were
collected by sawing off a portion of the trunk that revealed the outer bark pattern. They were placed
inside of a clear briefcase so they could be easily seen. Labels were placed on the clear briefcase
underneath the sample containing the same data as the herbarium. We collected fruits from trees
where possible and vacuum-sealed them in plastic shrink wrap. They were labeled with the
binomial name, common name, and identification number (Appendix C). From there, each of the
specimens could be clearly identified.
3.2 Plant Identification
Figure 7: Connor Bourgeois, Luke Trujillo, and Jax Sprague identifying the plants based on
photographs they had taken in the park using various applications. Photo taken by Alexa
Hancock.
In order to answer the prompt, our group decided to utilize the Pl@ntNet, iNaturalist, and
PictureThis apps to identify flora in El Caño Archaeological Park. With these apps, we could take
photos of the plants, live or from the camera roll, and discover the binomial and common names.
Pl@ntNet does this by having one select the organ of the plant being photographed and comparing
this feature to those of similar-looking plants. From there one selects the species with which it
18
most closely corresponds. Users can add their photos as a contribution so that others may use it for
comparison as well. Pl@ntNet is a collaborative community so others will validate fellow users’
flora observations to ensure that they have been identified correctly. In order to discover more
information about the species, users can click the information icon and be shown links to external
factsheets, as well as the family, genus, and species name. To maximize results, we took these
photos of multiple organs of each plant, such as the leaf, flower, fruit, and/or stem. The app
recommends taking straight-on and isolated photos of the organ to minimize interference and
provide clarity for easier identification (“PlantNet Plant Identification,” n.d.).
In instances where Pl@ntNet could not identify the specimen, we uploaded photos onto
iNaturalist and PictureThis. Neither of these apps requires the user to specify organs, but they
analyze the photo provided and make recommendations for the correct species based on visual
similarities. iNaturalist proved best for identifying the genus of plants but lacked many photos of
the suggested species, making it difficult to thoroughly identify the plant without further research.
PictureThis only analyzes a small portion of a photograph and makes three recommendations based
on the image. If none of the species match, the photo can be submitted for community analysis to
determine the species.
After identifying the plants, we took note of their approximate quantity in the park. It was
important to quantify them because this would help determine the number of signs necessary for
the park and the prominence of individual species, which would aid in the understanding of the
changing environment of the park. Other factors taken into consideration were the color and the
location of each plant. Since plants of the same species can come in different shades, it was
important to note these differences to avoid mislabeling them as a different flora altogether. We
could then inform Fundación El Caño that these were the same plant to avoid confusion. The
19
location of each plant was determined using a GPS system that allowed us to map its exact position
in the park.
For certain plants, none of our efforts succeeded in identifying them. In these instances,
we reached out to professional botanists. Before consulting experts, we would try to identify the
plant at least to the genus. We would submit the herbarium specimen sheet and photos of the plant
so the botanist could best identify the plant (Frank & Perkins, 2017). The botanist we contacted
was Laurencio A. Martinez. We emailed him photos of our plants so he could identify them. The
identified specimens were thoroughly labeled before being turned over to Fundación El Caño for
curation at the end of the project.
3.3 Data Synthesis
After collecting data at El Caño Archaeological Park, the data were entered into a
spreadsheet (Appendix A). This allowed us to manage, process, and compile the data set in a
relatively short amount of time. We took note of the family, genus, species, and common name,
the identifier's name, the identification year, region found, address, local description, latitude,
longitude, growth habit, height, collectors' names, and date collected. The sheet contained task-
keeping columns as well to see if the plant had been thoroughly collected, dehydrated, mounted,
labeled, stored, and filed. The data in the sheet was easily transferred to a separate document,
where the labels were formatted. These labels were printed and placed in the bottom corner of the
herbarium sheets (Appendix E).
Another method for data organization that was instituted consisted of a photograph filing
system (Appendix F). Folders were created for the various family names of the identified
specimens. From there, subfolders were made with the genus names. Inside the genus folders, we
20
created subfolders for the different species we believed the plants to be. The images were then left
in the genus folder until further notice, this was done to ensure against false positives as no plant
would be placed into its proposed species folder until a high enough certainty was reached.
3.4 Limitations
Our success at El Caño Archaeological Park was limited by a variety of geological and
financial challenges. Given the rural location of El Caño, there was little access to an internet
connection and WiFi in the park was very slow. This presented a limitation because plants had to
be identified after we had left the archaeological site. There were many cases when we were unable
to correctly identify a plant because of poor quality photographs. This was resolved by traveling
back to El Caño Archaeological Site for resampling and taking more photographs.
In addition, our group lacks expertise and formal education in the field of botany. This
presented a learning curve, slowing the group’s rate of progress on certain aspects of the project.
We conducted substantial research on botany and flora identification before arriving in Panama.
Additionally, we made contact with multiple staff members of the Smithsonian Tropical Research
Institute and various Engineers Without Borders chapters to gain information about archaeological
botany, Panamanian flora, Footprint Possibilities, and Pre-Columbian Central American
archaeology. While this did reduce the learning curve, there were still many things that needed to
be learned on-site.
Since El Caño is a relatively large park, we concluded early on that we would not have the
time to collect and press every species in the park. Pressing takes between two and four weeks to
thoroughly dry the plant (“How to Press and Preserve Plants,” n.d.). To facilitate the completion
of the project in seven weeks, we focused primarily on collecting samples of the more significant
21
and unique looking plants in the park. For the less significant species, like grass and weeds, we
collected data to identify the species without needing to preserve them. Because of this, we were
able to cover more ground and identify more plants in the timeframe of the project. To accelerate
the pressing process, we applied heavy-duty clamps as opposed to a rope to increase pressure and
placed the press next to a dehumidifier to absorb excess moisture. Within two weeks, the plants
were ready to be mounted.
Finally, one of the greatest limitations was funding for the project. Given that Fundación
El Caño and Footprint Possibilities are non-profit organizations, the amount of funding that was
provided to our project was limited. We had to purchase the necessary materials and craft the
presses on our own. Since the budget was non-existent, we also had to make many compromises
on materials, settling for plywood instead of gridded pieces of wood, replacing blotting paper with
newspaper, and using watercolor paper instead of herbarium mounting paper. Gridded wood would
have allowed for more even drying (“DIY Plant Pressing,” 2017), but the flat sheets of plywood
were sufficient at drying the plants. Since we added heavy-duty clamps and placed the press next
to a dehumidifier, they were able to dry quickly and evenly despite the different wood. An issue
with the newspaper was that it left ink behind on the leaves, but these markings were small and
concealed by gluing the tarnished side to the paper. Herbarium mounting paper is acid-free and
made of fabric (“Herbarium Mounting Paper,” n.d.), whereas watercolor paper is acid-free and
made of 50% cotton (“Fabriano 5,” n.d.), so it was a good, low-cost alternative.
22
CHAPTER 4: RESULTS
4.1 Findings
On the first trip to El Caño, the team traversed the perimeter of the park to determine its
size and biodiversity. Despite there being a high volume of plants, there were few unique species.
As a result, a goal was set to identify 50 plants and preserve 25 of them, including trees, shrubs,
herbs, and graminoids. Over the course of two weeks, 44 plant species were identified and 32 were
collected. Amongst these were 9 trees, 2 vines, 19 forbs/herbs, 3 shrubs, 6 subshrubs, and 5
graminoids.
These habits were identified from the United States Department of Agriculture’s Natural
Resources Conservation Service database. A tree is defined as a perennial, woody, vascular plant
with a single stem. A vine is a twining, vascular plant with relatively long stems, either woody or
herbaceous. A forb/herb is a vascular plant without significant woody tissue at or above ground.
They can be annual, biennial, or perennial, but they always lack significant thickening and have
perennating buds at or below the ground surface. Forbs/herbs include ferns, horsetails, lycopods,
and whisk-ferns. A shrub is a perennial, vascular plant with several woody stems arising from or
near the ground. The subshrub is a shorter shrub, never reaching more than 3 feet tall. Finally, a
graminoid is a grass or grass-like plant (“Growth Habits Codes and Definitions,” n.d.).
Upon discovering a new plant, the location was taken using GPS, the height was measured
in feet, photos were taken displaying each of the plant’s organs, a visual description of the plant
was recorded, and, if selected, a sample was cut. This was repeated throughout the park until no
more unique plants could be identified. An issue with this process was the number of dangerous
23
spiders in El Caño that prevented the team from going into certain areas, meaning there may be
more unidentified species. Nevertheless, the goal to preserve 25 species was exceeded.
The preservation process began with trimming the samples to size. They were then laid on
newspapers that were sandwiched between layers of cardboard and plywood. Every few days the
newspaper was exchanged as it had absorbed the moisture from the plants. After two weeks, the
samples were ready. They were glued to watercolor paper with superglue and epoxy to ensure they
would not detach. These sheets dried for a few hours before being placed in plastic page protectors.
The page protectors were collected in a scrapbook with each sheet containing two herbarium
specimens. Labels were taped onto the page protectors so as to not disturb the specimens.
In the case of bark, samples were sawed off the trunk and placed into a plastic briefcase
with dividers for each sample. A label was placed in the unit with its corresponding specimen to
clarify the identity. For fruits, they were shrink-wrapped in a vacuum sealer and labeled with a
marker. They were then attached to the scrapbook that contained their corresponding flower or
leaf specimen. This final product was delivered to Fundación El Caño for their use in the
comparative study.
4.2 Native, Non-Native, and Invasive Species
From the plants the team identified in El Caño, there was a variety of native, non-native,
and invasive species. Native species are those considered to be indigenous to a location, which in
this case is Central America. Likewise, non-native species are considered to be non-indigenous
but not dangerous to crop cultivation or environmental use. Non-native species were introduced to
a region by human help. Invasive species are species which are non-indigenous and have a
tendency to rapidly populate a region and take resources from the native plants or crops, displacing
24
at least one native species (Nodjimbadem, 2016). Whether a species is native, non-native, or
invasive has profound effects on its role in an ecosystem.
Figure 8: Invasive species vs. non-invasive species identified in El Caño Archaeological Park.
The team identified 44 different plant species in El Caño Archaeological Park. Eight of the
identified species are considered to be invasive. The ratio of invasive to non-invasive species
identified is illustrated in the table above. This is an important finding because invasive species
tend to rapidly change the ecosystem in which they exist, indicating that it is probable that the
biodiversity of El Caño is far different than the biodiversity during Pre-Columbian times.
25
Figure 9: Native species vs. non-native species identified in El Caño Archaeological Park.
Another interesting finding was the number of non-native species found inside of El Caño.
Of the 44 identified plants, 21 were found to be non-native. The ratio of non-native species to
native species is shown the table above. For example, Fagus sylvatica or “European Beech Tree,”
which is a large and lightly colored tree native to parts of Europe including Sweden, France, and
England. Other non-native species found are native to a variety of places: the Balkans, Africa,
Southeast Asia, and Australia.
Given the volume of non-native and invasive species, the team hypothesized that the
biodiversity of El Caño today is quite different than it was in Pre-Columbian time. This was further
supported after discussing the findings with the El Caño staff. It was indicated that most of the
trees in El Caño were planted recently in the park.
26
Figure 10: Map of the GPS coordinates of each plant identified in El Caño Archaeological Park.
The team recorded the latitude and longitude of each plant in El Caño Archaeological Park
in degrees, minutes, and seconds using a GPS system. In order to map the location on a satellite
image, they input the coordinates into an online calculator that converts the values into decimals.
Using a mapping program, the decimal coordinates were overlaid onto the most recent aerial view
available of El Caño. This picture was taken on April 2, 2018, dry season in Panama. In the dry
season, which lasts from January to April, there is little precipitation and much of the plant life
dies off. This is considered summer in Panama; it is the season when fruits sprout. For example,
Melothria pendula had only one or two cucumbers growing in September, while in the dry season
it would bloom more. Wet season lasts from May to December and is considered winter. It is
marked by frequent rainfall and flourishing plant life, with many more being green. The increase
of rainfall also leads to an increase in flooding, contributing to more species being brought into El
Caño Archaeological Park. Figure 10 has markers where no plant life is visible, meaning the
27
ecology is constantly changing in the park. In Appendix D, satellite imagery of El Caño was
included from the years 2018, 2017, 2013, and 2012. These satellite images further highlight the
rapid change in ecology that has happened in El Caño in the span of less than a decade.
4.3 Significance of Identified Species
Many of the plant species identified were utilized in traditional and folk medicinal
practices. Eclipta prostrata was used in Indian Ayurvedic medicinal practices to alleviate the
kapha dosha (Puri, 2003). Many plants also displayed antiseptic, antibacterial, antioxidant,
antiinflammatory, emetic, and purgative properties. Countless conditions were treated by these
plants, ranging from common colds to cancer and AIDS in the case of Momordica charantia
(“Bitter Melon,” 2019); malaria from Delonix regia (Fern, n.d.c), Cassia abbreviata (Fern, n.d.b),
Carica papaya (Fern, n.d.a), and Petiveria alliacea (Hernandez, 2014); diarrhea, dysentery, urine
retention, dehydration, and urogenital disorders in Mimosa pudica (Ahmad, Sehgal, Mishra, &
Gupta, 2012), Desmodium triflorum (Fern, n.d.d), and Laportea aestuans (Fern, n.d.e); and various
other disorders like diabetes, sinus infections, and stomachaches.
In addition to medicinal uses, several of these plants are integral parts of many cultures’
cuisines. Celosia argentea is eaten in West Africa and Southeast Asia (“Lost Crops of Africa,”
2006). Amaranthus spinosus is a valued food plant in Africa, Thailand, the Philippines, Maldives,
Mexico, Bangladesh, and Manipuri (Grubben & Denton, 2004). Ficus aurea produces an edible
fig fruit fibers that can be made into chewing gum (Harvey & Haber, 1998). Chili peppers produced
from Capsicum frutescens are a major part of Ethiopian cuisine (Pankhurst, 1968). By cooking
during the green and yellowing stages, Momordica charantia is eaten throughout Asia (“Bitter
Melon,” 2019). The fruit and seeds of Carica papaya can be eaten raw or cooked and are
28
throughout the world (Titanji, Zofou, & Ngemenya, 2008). The berries of Melothria pendula can
only be eaten when unripe and light green in color, otherwise they will have an extreme laxative
quality (“Melothria pendula,” n.d.). Several other plants were edible yet not an important part of
cultural cuisine.
Amongst the handful of trees identified were some that could be turned into furniture,
timber, firewood, and charcoal. Fagus sylvatica is often used in carpentry, flooring, firewood, and
indoor furnishings. Juglans regia not only produces an edible walnut, but the wood is prized for
flooring, instruments, furniture, and gunstocks (Elmore, 1944). Hura crepitans is used for timber
and decoration, but its sap can blind people if it makes contact with their eyes (“Hura crepitans,”
2018).
29
CHAPTER 5: CONCLUSIONS
5.1 Analysis
As seen in Figure 8, 18.2% of the plants in El Caño Archaeological Park are considered
invasive to Central America. Amongst the invasive species are several trees and noxious, fast-
growing weeds, including Gleditsia triacanthos, Solanum carolinense, Talinum paniculatum, and
Hura crepitans. These are significant for their destructive qualities. Gleditsia triacanthos destroys
pasture and outcompetes other crops. Solanum carolinense is highly toxic to consume and a
troublesome, noxious weed. Talinum paniculatum has long, deep roots that spread easily and are
hard to remove from a region. Finally, Hura crepitans contains a sap that can cause blindness if it
comes into contact with one’s eye. According to the director of Fundación El Caño, Dra. Julia
Mayo, the large trees were planted in the park. They are primarily fast-growing species, which
also accounts for the quickly changing ecology in photos from just one year ago.
Figure 9 shows that 47.7% of plants in El Caño are non-native species, indicating that they
were integrated into the park in recent history. Non-native species can grow in a location for many
reasons. For one, birds and other animals drop seeds into the park which grow and develop new
plants. Capsicum frutescens made a singular appearance in the park and was located to the side of
a tree, indicating that it likely grew from an animal dispersing some seeds. During wet season, the
high levels of rainfall increase flooding in the region. Floodwaters streaming from one area to
another disperse seeds throughout the park, thus changing the ecology every season. Another major
factor is landscaping. Many non-native and invasive species were planted in the park for their
aesthetic value, yet they do not accurately represent the nature of the El Caño region. Finally, since
the village of El Caño contains a sugarcane plantation and rice irrigation system, agricultural
30
practices are still in use (“Cultural Gold Artifacts Now on Display to Public,” 2019). Cultivating
crops alters the soil quality and changes what can easily grow. Depending on the exact agricultural
practices of the region, the land may have degraded over time and therefore is unable to support
the native plants. Since so many foreign plants are in the park, it is likely that the park today would
not be suitable to grow the original species.
5.2 Moving Forward
The purpose of this project was to identify the flora in El Caño Archaeological Park to
initiate a comparison study. During excavations of the tombs, archaeologists found plant matter
resins. Using the data collected through the course of this project, Fundación El Caño will compare
the modern environment to the plant matter identified in the tombs. This will provide compelling
historical insight into the diet, agriculture, and traditions of Pre-Columbian society. It will also
provide insight as to how the environment has changed over the past six centuries.
The team recommends that Fundación El Caño collect and identify more specimens in the
dry season, which runs from January to April. Given the tropical climate of Panama, the
environment changes dramatically between the two seasons. Identifying the species in the park
during the dry season would allow for plants which only grow during this season to be catalogued,
leading to a more comprehensive set of data for the comparative study.
31
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34
Image References
Figure 1: http://oda-fec.org/nata/download/bancorecursos/Noticias/noticia40-vitrinaTumba2.jpg
35
APPENDIX A: LIST OF PLANTS IDENTIFIED IN EL CAÑO ARCHAEOLOGICAL
PARK IN THE ORDER THEY WERE COLLECTED
Family
Name
Genus
Name
Species
Name
Common
Name Latitude
Longitud
e
Height
(ft)
Visual
Descripti
on
Amaranthac
eae Celosia argentea
"Silver
Cock's
Comb" (8,23,48.23) (80,30,4.6) 3.42
appears
frequently,
purple
gradient
flower,
leaves near
base
Asteraceae Eclipta prostrata
"False
Daisy" (8,23,48.1) (80,30,3.77) 1.38
small white
flowers,
green
undevelope
d buds, and
many
leaves
Poaceae Panicum
dichotomiflo
rum
"Smooth
Witchgrass" (8,23,48.47) (80,30,4.33) 4.58
golden
brown
appeared to
have very
small thin
seeds but
on a small
stem;
leaves were
spaced
throughout
the stem
Amaranthac
eae Amaranthus spinosus
"Spiny
Amaranth" (8,23,48.6) (80,30,4.3) 3
bushy
greenish-
brown
flowers;
leaves were
close to the
flowers
Asteraceae
Melampodiu
m divaricatum
"Hierba
Aguada" (8,23,48.5) (80,30,4.4) 2.5
small
yelllow
flowers;
leaves
throughout
the flower;
many
flowers on
36
the plant
Fagaceae Fagus sylvatica
"European
Beech" (8,23,48.6) (80,30,4.8) tree #1
Juglandace
ae Juglans regia
"Carpathian
Walnut" (8,23,48.55) (80,30,3.5) tree #2
Acanthacea
e Justicia comata
"Marsh
Water-
Williow" (8,23,48.2) (80,30,2.8) 2.67
had many
small white
flowers;
Inflorescenc
e; leaves
were distant
from the
flowers
Moraceae Ficus aurea
"Florida
Strangler
Fig" (8,23,46.4) (80,30,5.85)
tree #4;
biggest tree
in the park
Urticaceae Laportea canadensis
"Canadian
Wood
Nettle" (8,23,42.55) (80,30,1.7) 1.5
small white
flowers in
clumps that
are under
leaves;
spade
shaped
leaves with
rigid edges
Leguminosa
e Gleditsia triacanthos
"Honey
Locust" (8,23,42.4) (80,30,1.5)
tree #5;
aligator
bark
Leguminosa
e Sesbania herbacea
"Bigpod
Sesbania" (8,23,41.5) (80,30,1.45) 7.5
straight,
thin, and tall
plant;
leaves
extended
from
branches;
long oval
shaped
leaves;
many
leaves on
each
37
branch lined
in a row
Solanaceae Capsicum frutescens
"Bird
Pepper" (8,23,40.75) (80,30,4.95) 3
peppers
(varying in
color green,
red, orange)
in clumps
with smooth
club shaped
leaves
Urticaceae Laportea aestuans
"West
Indian
Woodnettle" (8,23,40.7) (80,30,5.2) 2.5
white
prickley
flower;
frequently
appears
and grows
straight and
tall
Leguminosa
e Mimosa pigra
"Giant
Sensitive
Plant" (8,23,41,3) (80,30,6.0) 6
fern like
leaves; very
small and
clumped
Cucurbatice
ae Momordica charantia
"Bitter
Melon" (8,23,41.3) (80,30,5.9) N/A
vines
climing tree
and
transvering
ground; with
5 point
yellow
flower and 5
point leas
1 Oplismenus
undulatifoliu
s
"Wavyleaf
Basketgras
s" (8, 23, 41.3) (80,30,5.9) 1
small spear
shaped
crinkly
leaves
Leguminosa
e Desmodium triflorum
"Three-
Flower
Beggarwee
d" (8,23,48.1) (80,30,4.8) 3 inches
round
leaves in
clumps of 3,
small
38
fuschia
flowers
Poaceae Cynodon dactylon
"Bermuda
Grass" (8,23,48.0) (80,30,4.6) 2.5
little
thingies
coming
from top,
very thin
stems
Leguminosa
e Mimosa pudica
"Sensitive
Plant" (8,23,47.9) (80,30,4.7) inches
small
fernish like
plant;
closes
when
touched
Asteraceae Galinsoga parviflora
"Gallant
Soldier" (8,23,47.8) (80,30,4.6) inches
arrowhead
shaped
leaves.
small white
petals with
a yellow
center
Commelina
ceae Commelina erecta
"Erect
Dayflower" (8,23,47.5) (80,30,4,6) inches
caved in
leaves,
purplish
white
flowers with
yellow
centers
Leguminosa
e Medicago polymorpha
"California
Burclover" (8,23,47.9) (80,30,4.9) inches
round
leaves 3ish
in a set; thin
and
abundant
Leguminosa
e Delonix regia
"Flamboyan
t" (8,23,46.2) (80,30,3.3) tree #6
Leguminosa
e Cassia abbreviata
"Long-pod-
cassia" (8,23,44.7) (80,30,3.2) tree #7
Leguminosa
e Hippocrepis emerus
"Scorpion
Senna" (8,23,42.0) (80,30,1.6)
tree #8,
yellow
flowers
39
Solanaceae Solanum carolinense
"Carolina
Horse-
Nettle" (8,23,41.9) (80,30,6.4) 8 inches
four pointed
leaf edges
on each
side, thorns
on leaves
Poaceae
Dichantheli
um
clandestinu
m
"Deertongu
e" (8,23,40.6) (80,30,6.9) 2.5 feet
sparse
seeds on
flowers,
long thin
leaves
Caricaceae Carica papaya "Pawpaw" (8,23,40.5) (80,30,6.9) 6 feet
tall, thin,
leaves on
branches
with many
points, fully
grown has
yellowish
flowers
and/or
green fruits
Marantacea Calathea latifolia
"Sweet
Corn Root" (8,23,41.3) (80,30,8.8) 5.75 ft
long, green
fronds,
purple
flower
cluster
Euphorbiac
eae Acalypha ostryifolia
"Hornbeam
Cottonleaf" (8,23,41.3) (80,30,8.8) 2.5 ft
nettle-like
leaves,
singular
green
sprout with
purplish
white
flowers
Portulacace
ae Talinum paniculatum
"Fameflowe
r" (8,23,41.3) (80,30,8.9) 2.17 ft
purple
flower
petals with
yellow
centers,
oval green
leaves
Cecropiace
ae Cecropia obtusifolia
"Trumpet
Tree" (8,23,41.3) (80,30,8.8) 5 ft
leaves with
8-9 spokes
Phytolaccac
eae Petiveria alliacea
"Garlicweed
" (8,23,41.1) (80,30,9) 4.92 ft
small white
flowers on
long strip
40
Cucurbitace
ae Melothria pendula
"Creeping
Cucumber" (8,23,48.1) (80,30,3.3) 4 ft
dark purple
fruit, spade
shaped
leaves
Euphorbiac
eae Hura crepitans
"Sandbox
Tree" (8,23,47.9) (80,30,3.3)
thorny tree,
tree #10
Euphorbiac
eae Euphorbia hypericifolia
"Graceful
Spurge" (8,23,46.8) (80,30,5.2) 0.67 ft
small green
and white
flowers,
oval leaves
Compositae Tridax
procumben
s
"Coatbutton
s" (8,23,46.3) (80,30,6.1) 1 ft
fluffy white
flower,
sharp green
leaves,
white and
yellow
flower
before fully
blooming
Asteraceae Emilia fosbergii
"Florida
Tasselflowe
r" (8,23,46.3) (80,30,6.1) 1 ft
green wrap
around
purple bud
flower
Cyperaceae Cyperus eragrostis
"Umbrella
Sedge" (8,23,45.5) (80,30,6.3) 1.33 ft
long thin
leaves,
blooming
brown
flowers
Leguminosa
e Alysicarpus vaginalis
"Alyce-
clover" (8,23,43.1) (80,30,3.7) 3 ft
thick oval
leaves
Urticaceae Urtica dioica
"Common
Nettle" (8,23,42.4) (80,30,3.7) 2 ft
hairy stem,
pointy
green spear
shaped
leaves,
small white
flowers
Euphorbiac
eae Acalypha pendula
"Dwarf
Chenille
Plant" (8,23,41.6) (80,30,4)
Capparacea
e Cleome serrata
"Toothed
Spiderflowe
r" (8,23,42.7) (80,30,4.9) 1ft
four white
petals with
yellow
extensions
41
APPENDIX B: SAMPLES OF THE PLANTS IDENTIFIED IN EL CAÑO
ARCHAEOLOGICAL PARK WITH HERBARIUM LABELS
Celosia Argentea
42
Eclipta Prostrata
43
Panicum dichotiflorum
44
Amaranthus spinosus
45
Melampodium Divaricatum
46
Momordica Charantia
47
Justicia comata
48
Laportea canadensis
49
Sesbania herbacea
50
Capsicum frutescens
51
Laportea aestuans
52
Mimosa pigra
53
Oplismenus_undulatifolius
54
Commelina Erecta
55
Hippocrepis_emerus
56
Solanum Carolinense
57
Calathea Latifolis
58
Acalypha Ostryifolia
59
Talinum Paniculatum
60
Cecropia Obtusfolia
61
Periveria Aliacea
62
Melothria Pendula
63
APPENDIX C: XILOTECA AND VACUUM-SEALED FRUITS
64
65
APPENDIX D: SATELLITE IMAGERY OF EL CAÑO ARCHAEOLOGICAL PARK TO
SHOW CHANGES IN ENVIRONMENT OVER TIME
66
67
68
69
APPENDIX E: PHOTOS OF THE HERBARIUM PRESS MADE BY THE TEAM
.
70
71
APPENDIX F: FOLDER FILING SYSTEM EXAMPLE